EP0237369A1 - Electric power supply provided with an alternating output voltage - Google Patents

Abstract

Electrical supply device intended to be interposed between a distribution network and a use network. According to the invention, the apparatus comprises a rectifier (17) which directly supplies without filtering an amplifier-inverter (20) delivering at its output the sinusoidal operating voltage (V), said amplifier-inverter receiving at its control input (23) a synchronous corrugated voltage and in phase with the voltage delivered by the distribution network. According to another feature of the invention, this supply is backed up by an amplifier (32) supplying the supply terminals (19) of the amplifier-inverter (20) with a voltage similar to that which the rectifier (17) would supply.

Description

The invention relates to a power supply device with alternating output, mainly intended for supplying computer equipment and / or systems for the acquisition and processing of low level signals, in particular requiring a power source. not generating radiated or conducted disturbances.

The invention relates more particularly to such a device capable of constituting a power source having a good yield and which is stable and / or backed up at least to cope with the blackouts of the distribution network.

• - Il ne doit pas être à l'origine de perturbations (bruits de commutation) rayonnées ou conduites, susceptibles d'induire dans les capteurs et leurs liaisons, des potentiels venant perturber les signaux faibles à mesurer et/ou traiter.
• - Il doit pouvoir, au besoin, assurer une certaine stabilisation de la tension alternative délivrée, pour éviter que des équipements sensibles soient soumis aux variations du réseau qui sont classiquement de ± 10\ par rapport à la tension nominale.
• - Il doit pouvoir faire face à des coupures de réseau, notamment au moins les coupures brèves ou microcoupures (jusqu'à 50ms) relativement fréquentes et, si possible, les coupures prolongées (plus rares) pouvant atteindre quelques minutes voire quelques heures.
• - Il doit assurer le cas échéant, l'isolement galvanique entre le réseau et le circuit d'utilisation.
• - Il doit avoir de préférence le meilleur rendement possible.

It is often necessary to insert an AC power supply device between the distribution network and certain systems such as computer equipment and / or chains of acquisition and processing of low level measurement signals, to prevent the functioning of such systems from being disturbed by network imperfections, in particular voltage variations and / or brief or prolonged outages. The qualities that one is entitled to demand from such a feeding device are the following:

• - It must not be the source of radiated or conducted disturbances (switching noises), likely to induce in the sensors and their connections, potentials disturbing the weak signals to be measured and / or processed.
• - It must be able, if necessary, to ensure a certain stabilization of the AC voltage delivered, to avoid that sensitive equipment is subjected to variations in the network which are conventionally ± 10 \ compared to the nominal voltage.
• - It must be able to cope with network outages, in particular at least brief or micro-outages (up to 50ms) relatively frequent and, if possible, prolonged outages (more rare) of up to a few minutes or even a few hours.
• - If necessary, it must provide galvanic isolation between the network and the user circuit.
• - It should preferably have the best possible yield.

Known systems rarely combine all these qualities.

For example, devices are known which use transformers of the "ferro-resonant" type. They provide mediocre voltage stabilization (typically + 5% for a variation of + 10d upstream). The energy reserve capable of dealing with micro-cuts is provided by a resonant circuit formed by an inductor coupled to the magnetic circuit and a capacitor. On the other hand, these systems have significant defects such as, for example, a poor dynamic response on a load impact and a significant variation in the output voltage as a function. of the frequency variation of the network. For this reason, they are generally not usable on networks of different frequencies. They are heavy, bulky and obsolete. Radio interference is to be feared, caused by the saturation current of the magnetic element. Last but not least, they cannot cope with prolonged network outages requiring the use of an electrochemical accumulator.

When considerable autonomy is required, an inverter supplied by a rectifier and an electrochemical accumulator of suitable capacity are often used, inserted in parallel between the rectifier and the supply terminals of the inverter. The latter therefore operates from a DC voltage filtered by the accumulator itself. The inverter, responsible for restoring a sinusoidal voltage from a DC voltage is often of the "pulse width modulation" type, with transistors or thyristors, operating at high frequencies, which makes their operation difficult to extreme temperatures. The switching of the semiconductors which they comprise often creates electrical disturbances which make their use difficult in the vicinity of sensitive measuring devices.

To improve the efficiency and reduce the bulk, it has also been proposed to use a switching inverter operating at high voltage, without transformer and connected, upstream, on the one hand, to a switching rectifier. connected to the distribution network and supplying a continuous high-voltage and, on the other hand, to a DC-DC converter supplied by an electrochemical accumulator, replacing the network in the event of failure thereof. The converter is in a way connected in parallel to the output of the rectifier, the accumulator being moreover connected to a charger sized only to ensure its recharging. Such a system is unreliable due to the large number of switching circuits. Electrical disturbances are significant or difficult to control. This principle is difficult to implement when high powers are involved.

Another known concept consists in using the distribution network normally and quickly replacing it, by switching, with a backup source in the event of a power cut. This switching can be done by the set of static contactors (thyristors) switching on the load an inverter operating at no load as long as the network is present. The inverter is powered by a battery permanently connected to a charger. With such a system, the efficiency is good in mains operation and the inverter can be reduced in size since it is only used during the duration of a network failure. However, a disturbance is inevitable when switching the solid state contactors. Usually, there is no isolation from the network and it is not possible to stabilize the operating voltage. Some of these drawbacks can be avoided by combining a ferro-resonant inverter with such a system, but in this case, finds all the drawbacks mentioned above, such as, for example, the variation of the output voltage as a function of frequency and / or load and a poor dynamic response.

The invention combines most of the advantages of the various known systems described above, while avoiding their main drawbacks. The primary purpose of the invention is to propose an electrical power supply device with alternating voltage output having both an excellent efficiency and a low level of electrical disturbances (radiated or conducted) while being suitable, on the other hand, effective regulation of the output voltage and / or the addition of an auxiliary energy source capable of replacing the network in the event of its failure.

In this spirit, the invention relates first of all to an electrical power supply device with alternating voltage output, of the type comprising a rectifier connected to be supplied by a distribution network and thus deliver at its output a corrugated rectified voltage, characterized in that said rectifier is connected to supply terminals of an amplifier-inverter and in that a control input of this amplifier-inverter is connected to a means generating a synchronous undulated voltage and in phase with the voltage delivered by said distribution network.

By "amplifier-inverter" is meant a particular type of inverter comprising, on the one hand, an amplification stage operating in class B (or possibly in class C, as will be seen below) essentially responsible for developing a rippled output voltage in response to a signal applied to its control input or to transmit (in the case of class C operation) the voltage delivered by the rectifier, and on the other hand, a means capable of restoring an alternating voltage to from the waveform delivered by said amplification stage. In the event that a voltage regulation alternative output is desired, we will use more specifically an amplification stage operating in class B and responsible for delivering at its output, a wavy voltage formed of a succession of "sinusoid arches" of the same polarity. Most often, a transformer will then act as a means capable of restoring a sinusoidal alternating voltage from said sinusoid arches.

With such an arrangement, and according to an important characteristic of the invention, the efficiency is excellent (greater than 75%) because the losses in the amplifier-inverter are a function of the voltage difference between the wave delivered by the rectifier and that (synchronous and in phase) delivered by the amplification stage. A simple regulation loop, conventional, between the output of the amplifier-inverter and a comparator connected to its input will, if necessary, obtain regulation of the sinusoidal output voltage.

On the other hand, if the regulation of the output voltage is not essential for the envisaged application, we can further improve the efficiency by modifying the amplification stage to make it work in class C. In this case, both branches of the amplifier will be subject to operating in all or nothing and not in linear, so that said amplification stage in class C will directly transmit the "sinusoid arches" to the transformer responsible for reconstructing an alternating sinusoidal output voltage.

In the two cases envisaged above, the amplifier-inverter can easily be coupled to an emergency source of electrical energy, such as a capacitor, at least (case of micro-cuts) or an electrochemical generator (to face prolonged outages).

In this spirit, the device according to the above definition is further characterized in that an auxiliary amplifier connected to be supplied by means of electrical energy storage, at its output connected to the power supply terminals of the amplifier-inverter, for example by means of a unidirectional conduction element such as a diode and that said auxiliary amplifier has its control input connected to a means generating a synchronous undulated voltage and in phase with the voltage delivered by said distribution network.

• - la figure 1 est un schéma-bloc d'un mode de réalisation possible d'un appareil d'alimentation électrique conforme à l'invention; ⁹
• - la figure 2 est un schéma illustrant partiellement un mode de réalisation possible de l'amplificateur-onduleur de la figure 1;
• - la figure 3 est une variante de la figure 2; et
• - les figures 4a et 4b sont deux chronogrammes illustrant l'amélioration obtenue par la mise en oeuvre du principe de l'invention;
• - la figure 5 est un schéma-bloc d'une variante de la figure 1.

The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of several possible embodiments of an electrical power supply device in accordance with its principle, given solely by way of example and made with reference to the accompanying drawings in which:

• - Figure 1 is a block diagram of a possible embodiment of an electrical supply device according to the invention; ⁹
• - Figure 2 is a diagram partially illustrating a possible embodiment of the amplifier-inverter of Figure 1;
• - Figure 3 is a variant of Figure 2; and
• - Figures 4a and 4b are two timing diagrams illustrating the improvement obtained by the implementation of the principle of the invention;
• - Figure 5 is a block diagram of a variant of Figure 1.

Referring to the diagram, and in particular to FIG. 1, there is shown an electrical power supply device 11, rescued against the micro-cuts of the AC distribution network connected to the access terminals V _{AC '} Optionally the device is associated to a DC voltage source 12 capable of being connected to its access terminals V _CC , to give it greater autonomy. This DC voltage source 12 simply consists of an electrochemical accumulator 13 whose terminals are connectable to the V _DC terminals and of a charger 14 whose output is connected to the accumulator.

This charger is supplied by the distribution network but only sized to ensure the charge of the accumulator.

The supply device 11 comprises a transformer 16, step-down, the primary of which is connected to the terminals V _AC and the secondary of which is connected to a rectifier 17. The output of the latter is directly connected to the terminals supply 19 of an amplifier-inverter 20. The output of the amplifier-inverter 20 is connected to output terminals V _S delivering an alternating, sinusoidal operating voltage. It should be noted, at this stage of the description, that unlike known devices which include capacitors (or an electrochemical accumulator) connected in parallel to the output of rectifier 17 to obtain a DC supply voltage for the inverter, also rigorously filtered as possible (of the V _RF type, FIG. 4n), the amplifier-inverter 20 is directly supplied by "sinusoid arches" (of the V _R type, FIG. 4b). This important and specific feature of the invention is one of the reasons for the good performance of the device despite the use of a linear amplification stage, operating in class B, in the amplifier-inverter 20. The latter meets the definition given above. FIG. 2 shows for example, a power stage of the "Push-Pull" type with two transistors Q ₁ , Q ₂ . The collectors of these transistors are charged by the primary winding L ₁ of an output transformer 21. This primary winding L ₁ has a midpoint connected to one of the supply terminals 19. The secondary winding L ₂ of the transformer 21 is connected to the output terminals V _S. A capacitor is mounted in parallel on this winding.

A control circuit 18 (FIGS. 2 and 5), the design of which is within the reach of those skilled in the art, comprises a control input 23 which also constitutes the control input of the amplifier-inverter and is connected for drive the bases of the transistors Q ₁ , Q ₂ according to a class B operating regime. Thus, the power stage, polarized in class B, can be directly driven by an undulated, alternating voltage, applied to its control input 23. This wavy voltage is developed at from a generator means 24 synchronized with the voltage of the distribution network. To do this, it includes a pilot oscillator 25 operating at the same frequency as the distribution network and a synchronization circuit 26 connected to the rectifier or to the distribution network by a link 27. The design of this synchronous generator means is within reach of the skilled person. Thus, as long as the distribution network is operating normally, the voltage available at the output 28 of the generator means 24 is synchronous and in phase with that of the distribution network. If the mains voltage disappears, the oscillator 25 continues to operate at the same frequency and, as soon as the mains voltage reappears, the synchronization circuit 26 acts to cancel any phase difference between the signal available at the output 28 and the network voltage.

Furthermore, the amplifier-inverter 20 includes or is associated with feedback means, symbolized here by a feedback loop 30 established between the output of the amplifier-inverter and an input of a differential comparator 31 The other input of this comparator is connected to the output 28 while its own output is connected to the control input 23 of the amplifier-inverter 20. These conventional feedback means provide regulation of the alternating voltage available at the output terminals V The latter is therefore in particular independent of variations in the voltage of the distribution network which result in variations in amplitude of the "sinusoid arches" V _R (FIG. 4b) delivered by the rectifier 17.

In addition, to compensate for a possible failure of the distribution network, an auxiliary amplifier 32 (symbolized here by a transistor operating in linear mode) is connected to be supplied by means of electrical energy storage constituted by a capacitor C ₁ and / or the accumulator 13. The output 33 of this auxiliary amplifier is connected to the supply terminals 19 of the inverter amplifier 20 by via a diode 34. The electrical energy storage means are at least constituted by the capacitor C ₁ which has sufficient capacity to supply the auxiliary amplifier 32 (and consequently the inverter amplifier 20 under load ) during a blackout in the distribution network. The capacitor is normally kept cbarged by a load circuit connected to the network and symbolized here by a diode D ₁ connected between the output of the rectifier 17 and the capacitor C ₁ . A contactor K is interconnected between the amplifier 32, on the one hand, and the capacitor C ₁ and the accumulator 13 (possibly), on the other hand. For a position of the contactor K, the amplifier 32 is supplied by the capacitor C ₁ and the sinusoidal voltage available at the output V _S is cleared of all the micro-cuts in the distribution network. If the source 12 is connected to the terminals V _CC , the contactor K is toggled to its other position and the installation then acquires a longer autonomy which depends on the capacity of the accumulator 13.

The control input 35 of the auxiliary amplifier 32 (which also operates in class B) receives the signals available at the output 28 via a rectifier 36. Under these conditions, the auxiliary amplifier (which does not is not here of the "Push Pull" type) receives at its input sinusoid arches similar to those which are delivered by the rectifier 17, synchronous and in phase with them. Such amplified "arches" are therefore available at output 33. However, the gain of the auxiliary amplifier 32 is adjusted so that the "arches" that it delivers have a voltage slightly lower than the voltage of the "arches" delivered by rectifier 17 when the network delivers a minimum sinusoidal voltage (for example, nominal voltage -10%). Under these conditions, the diode 34 is normally blocked as long as the distribution network operates normally and the auxiliary amplifier 32 operates at no load, consuming relatively little energy.

Furthermore, because the amplifier-inverter is directly supplied by synchronous "sinusoid arches" and in phase with its control voltage, the losses in the latter are very low.

The comparison of FIGS. 4a and 4b makes it possible to understand why the amplifier-inverter 20 operates with excellent efficiency. On the two timing diagrams, the waveform V _SA delivered at the output of the power stage of the amplification circuit of the amplifier-inverter is shown. If the supply voltage of the latter was a carefully filtered DC voltage V _RF (FIG. 4a), the losses in the amplifier-inverter would, at all times, be a function of the potential difference between V _RF and V _SA . However, since the amplifier-inverter is directly supplied by synchronous "sinusoid arches" V _R (FIG. 4b) and in phase with V _SA , the losses (always a function of the potential difference between V _{R at all times)} and V _SA ) are much lower. The curves P ₁ and P ₂ in broken lines reported in Figures 4a and 4b respectively illustrate the losses, in both cases, assuming the sinusoidal current and in phase with the voltage.

In this case, the reduction in losses is more than 50%. It is also important to note that if the current and the voltage are out of phase, which is generally the case, the reduction in losses is even greater. Thus, for a 45 'phase shift, the reduction in losses is of the order of 65%.

Furthermore, the operation in the event of a distribution network failure is as follows. If the DC voltage source 12 is not connected, the contactor K is placed in a position such that the capacitor C ₁ is in service. As soon as the voltage V _R goes below a predetermined low threshold, the diode 34 is released instantly without creating the slightest disturbance and the amplifier-inverter 20 is then supplied by "sinusoid arches" generated this time by the amplifier 32 itself supplied by the electrical energy accumulated in the capacitor C ₁ . This arrangement is sufficient to cope with micro-cuts in the network, but it is obvious that the supply device 11 cannot be rescued for a longer period of time unless the DC voltage source 12 is connected and the accumulator 13 is . substituted for capacitor C ₁ by operating switch 'K. During a period of emergency operation, the efficiency of the assembly is poorer because the auxiliary amplifier 32 operates under conditions similar to those illustrated in FIG. 4a, but this drop in efficiency is only effective during a very small part of the usage time. To avoid oversizing the amplifier 32 and especially to cope with prolonged periods of autonomous operation, it is possible to "distribute" the additional dissipation between the auxiliary amplifier 32 and the amplifier-inverter 20. It suffices to provide for the input of the auxiliary amplifier 32 a means suitable for increasing the amplitude of the control signal and consequently increasing the amplitude of the "sinusoid arches" delivered to the output 33. This means would for example be associated with a switching means, possibly delayed, to be put into service during a prolonged failure of said distribution network. The losses in amplifier 32 then decrease while those of amplifier 20 increase slightly.

FIG. 3 illustrates a possible variant of the power stage of the amplifier-inverter 20. This amplification stage is always polarized to operate in class B but this time includes a bridge arrangement of four transistors T ₁ , T ₂ , T ₃₁ T ₄ , the primary L ' ₁ of the output transformer being simply connected in a diagonal of this bridge. With such an arrangement, in particular, it is possible to operate from a high-voltage rectifier directly connected to the network, that is to say to remove the isolation transformer 16 from the figure. 1. You must then (if necessary) use a high-voltage accumulator (of the order of 320 Volts) to supply the auxiliary amplifier. Operation from a low-voltage accumulator (48 Volts) is however possible if two switchable primary windings are provided, defining different transformation ratios of the output transformer 21. Finally, it should be noted that this type of assembly allows to remove the output transformer by means of some modifications in the control circuit of the bridge assembly, these modifications being within the reach of the skilled person.

Transposition into three-phase poses no problem. It suffices to triple the circuits with pilot oscillators suitably out of phase with each other.

Finally, as mentioned above, it is possible to bias the power stage of the amplifier-inverter 20 to make it operate in class C if the regulation of. the output voltage V is not sought. The device then gains further in efficiency during periods of operation on the network and the arrangement retains all its advantage for the addition of the means described above likely to cope with a network failure.

The advantages of the system which has just been described are numerous. The main ones are the excellent efficiency and the absence of radiated or conducted noise, due to a linear operation excluding any operation in high-frequency switching. The service life of transistors operating in linear, class B, is much longer than that of the static switching devices generally used in this type of device. Besides the possibility of eliminating some of the transformers described above (or even all), the device of the invention further gains in compactness by the fact that the rectified voltage is not filtered by a group of bulky electrochemical capacitors. Reliability is further improved. The possibility of operating without an electrochemical accumulator (compensation for micro-cuts only) gives the device of the invention all the advantages of a ferro-resonant regulator without any of its drawbacks. In particular, the dynamic response of the system is excellent due to the linear operation of the amplification circuits of the amplifier-inverter. The device is able to cope with very large momentary overloads by increasing the number of transistors, in parallel, of the power stages and / or by delaying the response time of the current limiting circuits of the amplifier. The output voltage does not vary according to the frequency of the network and the same device can, with some banal modifications, be adapted to operate in connection with a distribution network of any frequency, in particular 50Hz, 60Hz or 400Hz. Finally, due to the absence of capacitive filtering of the rectified voltage, the form factor of the current is substantially the same as that imposed by the user. In other words, the device according to the invention does not introduce cos Ø between the distribution network and the use network.

The variant of FIG. 5, in which the elements similar to those of FIG. 1 bear the same numerical references, is notably remarkable by a charging circuit of an electrochemical accumulator and therefore, particularly indicated when the device is associated with a direct voltage source 12 capable of being connected to its terminals V _cc to give it greater autonomy. This DC voltage source 12 is here simply constituted by an electrochemical accumulator 13 whose poles are connectable to the terminals V _CC as well as to terminals V _RC constituting the output of a recharging circuit integrated into the device 11, which will be described later. The apparatus 11 is essentially identical to that of FIG. 1 but the transformer 21 has an auxiliary secondary winding L ₃ . Thus, the above-mentioned counter-reaction means also provide a regulation of the voltage available at the terminals of this winding L ₃ . In addition, the apparatus comprises a rectifying circuit 40 connected to an AC voltage output of the amplifier-inverter 20, more particularly here constituted by the terminals of the winding L ₃ . This rectification circuit forms most of the means for recharging the electro-chemical accumulator 13. Its rectified voltage output is filtered by a capacitor 41 and connected. at terminals V _RS . The regulation of the recharging current is perfectly mastered because the voltage delivered by the winding L ₃ is very stable since it "benefits" from all the regulation circuits provided for stabilizing the voltage V _S. A means forming a controlled switch comprises a control circuit 42 connected to be sensitive to the presence of a voltage delivered by the distribution network or of a voltage dependent on the latter. Said controlled switch means is interconnected at a point located between the inverter amplifier and the V _RC connection terminals to interrupt the charging of the accumulator when the voltage of the distribution network falls below a predetermined threshold. In the nonlimiting example described, the means forming a controlled switch is an electromagnetic relay or the like, a contact 43 of which is interconnected in series in the connection between the winding L ₃ and the rectifier 40. The above-mentioned control circuit 42 is therefore simply the control winding of this relay, controlled by the network. This arrangement makes it possible to interrupt the charging of the accumulator 13 when the latter is called upon to supply the inverter amplifier 20, via the amplifier 32, during a network failure.

It therefore appears that the apparatus 11 which has just been described behaves like a network "conditioner", responsible for stabilizing the voltage of this network and provided with at least part of the means necessary to ensure recharging of the accumulator 13. For this, it is sufficient to provide at least one auxiliary winding such as L ₃ , the other elements of the recharging network being able to be placed at inside the device 11 or on the contrary inside the case of the DC voltage source 12.

Claims (17)

1- Electric power supply device with alternating voltage output, of the type comprising a rectifier (17) connected to be supplied by a distribution network and thus deliver at its output a corrugated rectified voltage, characterized in that said rectifier is connected to supply terminals (19) of an inverter amplifier (20) and in that a control input (23) of this inverter amplifier is connected to a means generating a synchronous ripple voltage (24) and in phase with the voltage delivered by said distribution network (V _AC ). 2- A power supply device according to claim 1, characterized in that said amplifier-inverter (20) comprises or is associated with feedback means (30,31) to stabilize its output voltage in the vicinity of a predetermined value. 3- Apparatus according to claim 1 or 2, characterized in that an auxiliary amplifier (32) connected to be supplied by means of electrical energy storage (C ₁ , 12) has its output connected to said supply terminals ( 19), for example by means of a unidirectional conduction element such as a diode (34) and that said auxiliary amplifier has its control input connected to a means generating a synchronous undulated voltage (24) and in phase with the voltage delivered by said distribution network. 4- Apparatus according to claim 3, characterized in that the generator means driving said amplifier-inverter (20) is also the generator means driving said auxiliary amplifier (32). 5- Apparatus according to claim 4, characterized in that said generating means comprises a pilot oscillator (25) delivering a similar undulated voltage and of the same frequency as that of said network and a synchronization circuit (26) connected to said rectifier or to said network. 6- Apparatus according to one of claims 3 to 5, characterized in that the aforementioned electrical energy storage means comprise at least one capacitor (C ₁ ) of sufficient capacity to supply said auxiliary amplifier during a brief interruption of said distribution network, said capacitor being connected to a charging circuit (D ₁ ) linked to said network. 7- Apparatus according to one of claims 3 to 6, characterized in that the aforementioned electrical energy storage means comprise an electrochemical accumulator (13) sized to supply said auxiliary amplifier (32) during a prolonged outage of said distribution network . 8- Apparatus according to one of the preceding claims, characterized in that said amplifier-inverter (20) comprises a power stage with transistors operating in class B. 9- Apparatus according to claim 8, characterized in that said amplifier-inverter comprises a transformer connected to the output of said power stage. 10- Apparatus according to claim 9, characterized in that said transformer comprises a primary winding (L ₁ ) at mid point connected to a power stage with transistors of the "Push-Pull" type (Q ₁ , Q ₂ ). 11- Apparatus according to claim 8 or 9, characterized in that said amplifier-inverter (20) comprises a power stage in bridge of transistors operating in class B (Figure 3). 12- Apparatus according to claim 1, characterized in that said amplifier-inverter (20) comprises a power stage with transistors operating in class C. 13- Apparatus according to one of claims 3 to 12, characterized in that it comprises a means suitable for increasing the amplitude of the control signal of said auxiliary amplifier during a failure of said distribution network. 14- Electric power supply device alternating voltage according to claim 7, characterized in that it comprises a rectifying circuit (40) connected to an alternating voltage output (L ₃ ) of the amplifier-inverter (20) and forming at least part of the means of recharging of an electrochemical accumulator (13). 15- An electrical power supply device according to claim 14, characterized in that it comprises a means forming a controlled switch, a control circuit (42) of which is connected so as to be sensitive to the presence of a voltage delivered by or dependent on the network. distribution and in that this switch means is interconnected between a point located between said amplifier-inverter (20) and the poles of said electrochemical accumulator to interrupt the charging of the latter when said voltage falls below a predetermined threshold. 16- Apparatus according to claim 15, characterized in that said controlled switch means is an electromagnetic relay or the like, a control winding (42) is connected to be supplied by the voltage of the AC distribution network or by a voltage representative of the latter and a contactor (43) of which is interconnected in series in the connection between said alternating voltage output (L ₃ ) and said poles. 17- Power supply apparatus according to one of claims 14 to 16 wherein said amplifier-inverter comprises a transformer connected to the output of a power stage with transistors operating in class B, characterized in that the voltage output aforementioned alternative of the amplifier-inverter (20) consists of the terminals of a particular winding (L ₃ ) of a transformer of the amplifier-inverter.

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